In order to understand how cold ions (< 10 eV) evolve temporally and spatially within the inner magnetosphere (L < 6.5) during geomagnetic storms, we performed superposed epoch analyses on the partial ion densities of H⁺ (N_H+), He⁺ (N_He+), and O⁺ (N_O+) using flux data from the Van Allen Probes in the 1-10 eV energy range. The analyses were conducted on a set of 14 large storms (Dst < -100 nT) over a five-year period from September 2013 to September 2017. We examined the ion density ratios (N_H+/N_e, N_He+/N_e, and N_O+/N_e) normalized to the electron number density (N_e) and found that the N_O+/N_e ratio dramatically increases during the early recovery phase outside the model plasmapause. The enhanced N_O+/N_e ratio persisted for a period exceeding three days subsequent to the Dst minimum. The variation of the N_He+/N_e ratio observed outside the plasmapause exhibited a trend similar to that of the N_O+/N_e ratio during the recovery phase. However, the N_He+/N_e ratio is more than an order of magnitude smaller than the N_O+/N_e ratio. In contrast to the N_He+/N_e and N_O+/N_e ratios, the N_H+/N_e ratio does not exhibit a significant increase during the recovery phase. The enhanced cold O⁺ ions outside the plasmapause exhibit a bi-directional, predominantly field-aligned population, and the N_O+/N_H+ ratio decreases in the afternoon sector (MLT = 12-18 hr). Based on these observations, we suggest that the enhanced cold O⁺ ions outside the plasmapause drift into the inner magnetosphere from the tail during large storms.